Numerical Simulation on Fluid-Solid Coupling of Gate with Different Structure Types of Hemline in Deep Hole

Jun Xing Wang; Li Qiang Chen; Yu Ting Chen

doi:10.4028/www.scientific.net/AMM.444-445.239

Paper Titles

The Development and Application of Meshless Method
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Parallelized Aeroelastic Investigation Based on Delaunay Graph Mapping
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Extreme Transient Flow in Pumping System due to a Tripping Pump Disturbance
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Numerical Simulation on Fluid-Solid Coupling of Gate with Different Structure Types of Hemline in Deep Hole
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Numerical Analysis on the Rapid Starting Period in a Screw-Type Centrifugal Pump
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Numerical Investigation of Flow around a Triangle Cylinder Using a Multiscale Turbulence Model
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Improving the Robustness of Adjoint-Based Airfoil Drag Reduction Design
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Characteristics of Train Wind and Analysis of Personnel Safety in Double-Line Shield Tunnel
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 444-445Numerical Simulation on Fluid-Solid Coupling of...

Numerical Simulation on Fluid-Solid Coupling of Gate with Different Structure Types of Hemline in Deep Hole

Abstract:

Although there are some achievements of flow-induced vibration of plane steel gate, few is about the influence on gate caused by the difference of structure types of gates hemline. This paper studies on the flow pattern, natural vibration characteristics and dynamic response of four typical types of gates hemline in deep hole of Kajiwa Hydropower Stations service gate. Based on model test and numerical simulation and considering the flow pattern under the gate and in the gate slot, the natural vibration characteristics and the gates dynamic response, it is suggested to use an anteversion angle and a caster angle (type D for short) for the hemline of the type II gate slot. The optimal factors of a gates hemline in a concrete project can be optimized by numerical simulation.

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Periodical:

Applied Mechanics and Materials (Volumes 444-445)

Pages:

239-243

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.444-445.239

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Online since:

October 2013

Authors:

Jun Xing Wang, Li Qiang Chen, Yu Ting Chen

Keywords:

Fluid Solid Coupling, Numerical Simulation, Plane Steel Gate, Structure Type of Gates Hemline, Type II Gate Slot

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